WO2012150194A1

WO2012150194A1 - Method and device for producing electrode coils

Info

Publication number: WO2012150194A1
Application number: PCT/EP2012/057824
Authority: WO
Inventors: Konrad Holl; Markus Pompetzki; Robert SEKLER; Heiner STELZIG; Stefan STOCK
Original assignee: Volkswagen Varta Microbattery Forschungsgesellschaft Mbh & Co. Kg
Priority date: 2011-05-02
Filing date: 2012-04-27
Publication date: 2012-11-08
Also published as: DE102011075063A1; CN103503217A; CN103503217B; KR20140044326A; EP2705556A1; US9373865B2; EP2705556B1; US20140053383A1; JP2014519145A

Abstract

The invention relates to a method for producing electrode coils. A strip- or band-shaped anode and a strip- or band-shaped cathode are provided, and flat arrester lugs are formed on at least one longitudinal face of the anode and the cathode at varying distances from one another and/or contours are cut into the longitudinal faces of the electrodes. The anode and the cathode are wound together with a strip- or band-shaped separator into a coil that has the sequence anode/separator/cathode. The method is characterized in particular in that the arrester lug-forming process and/or the contour-cutting process and the winding process overlap in time. The invention also relates to a device for carrying out such a method.

Description

description

Method and device for producing electrode windings

The present invention relates to a method for producing electrode coils and to a device suitable for carrying out the method.

The term "battery" originally meant several series-connected galvanic cells in one housing, but today individual galvanic cells are often referred to as "battery." During the discharge of a galvanic cell, an energy-supplying chemical reaction takes place, which consists of two electrically coupled ones At the negative electrode, electrons are released in an oxidation process, resulting in an electron current via an external load to the positive electrode, from which a corresponding amount of electrons is taken in. At the positive electrode, a reduction process takes place There is an ion current corresponding to the electrode reaction within the cell. - -

This ionic current is ensured by an ionically conductive electrolyte. In secondary cells and batteries, this discharge reaction is reversible. It is therefore possible to reverse the conversion of chemical energy into electrical energy that took place during the discharge. If the terms "anode" and "cathode" are used in this context, the electrodes are usually named according to their discharge function. The negative electrode is in such cells so the anode, the positive electrode, the cathode.

Like secondary cells and batteries, capacitors can also reversibly store electrical energy, but not in a chemical form but in an electric field between two electrically conductive surfaces, the capacitor electrodes, which are usually arranged at a small distance from each other. Since electrical charge in a capacitor is not released or stored as a result of a chemical reaction, it can be picked up and released very quickly. The energy density of a capacitor is usually much lower than that of a battery.

Among the known secondary cells and batteries comparatively high energy densities are achieved in particular of lithium-ion batteries. Lithium-ion batteries often contain a stack of cells consisting of several single cells. However, in particular, high-capacity cells and batteries are often constructed as winding cells having strip-shaped or band-shaped electrodes in wound form (electrode coils). This is also the preferred design of capacitors.

Usually secondary cells and batteries as well as capacitors with a winding structure have a wound composite of areal electrodes and separators with the sequence positive electrode / separator / negative electrode. In the case of secondary cells and batteries, the electrodes usually include - - Metallic current conductors and electrochemically active components and electrochemically inactive components. As electrochemically active components (often referred to as active materials) come for secondary lithium-ion batteries, all materials in question, which can absorb lithium ions and release again. The state of the art in this regard for the negative electrode in particular carbon-based particles such as graphitic carbon or for the intercalation of lithium capable non-graphitic carbon materials. Furthermore, it is also possible to use metallic and semimetallic materials which can be alloyed with lithium or composites of such materials with, for example, carbon-based materials. For the positive electrode in particular lithium metal oxide compounds and lithium metal phosphate compounds such as L1C0O ₂ and LiFeP0 ₄ in question. Electrochemically inactive components are first and foremost electrode binders and the abovementioned current conductors. Electrodes from the electrodes are supplied or removed via the current conductors. The electrode binders ensure the mechanical stability of the electrodes and ensure contact between the particles of electrochemically active material with each other and with the current conductor. As separators, in particular microporous plastic films in question.

In the case of capacitors, the electrodes are usually electrically conductive substrates such as metals. As a separator, for example, a non-electrically conductive nonwoven fabric, a porous plastic film (e.g., polyethylene) or a non-electrically conductive porous ceramic layer (e.g., alumina) may be used.

For the production of electrodes for secondary batteries and cells, pastes, comprising the mentioned electrochemically active and inactive components, are applied in the form of thin layers to electrical conductors, dried and dried in the form of thin layers - - brought the desired fit. Usually, the layers are then rolled and pressed and optionally subsequently combined with separators and counterelectrodes. However, problems can arise in particular in the production of wound cells.

The dissipation of current from electrode windings via Ableiterfahnen. It is common practice in the production of electrode coils to be wound strip or ribbon-shaped electrodes with a plurality, preferably a plurality of Ableiterfahnen to load when charging or discharging the electrodes as evenly as possible. It is accordingly customary to provide distributed over the entire length of an electrode strip to be wound Ableiterfahnen. In the finished winding these Ableiterfahnen usually protrude frontally out of the winding. In this case, collector tabs of the same polarity should be grouped, in particular overlapping in a stack-shaped arrangement, so that they can be connected to one another as easily as possible, for example by welding. In order for such a grouping to be obtained and the trap lugs, e.g. in spiral windings, not in a more or less random radial distribution, it must be taken into account that the radius of an electrode winding increases outwardly with each turn of the winding. If arrester lugs are arranged at regular intervals on the longitudinal side or sides of an electrode strip, this leads to a radial offset of the conductor lugs in the winding.

In practice, this problem is addressed by allowing the spacing between adjacent conductor tabs along the electrode strip to be wound to rise in the direction of the end of the strip in the winding. The required distances can be calculated quite easily considering the thickness of the electrodes. However, especially with the electrodes of secondary - -

Batteries and cells within certain tolerances to variations in thickness in the longitudinal direction. With a minimum thickness variation of +/- 1 μm, the resulting offset can already be several millimeters in a winding cell with more than 100 turns.

The present invention has for its object to find a solution to this problem.

This object is achieved by the method having the features of claim 1 and by the apparatus having the features of claim 5. Preferred embodiments of the method according to the invention are specified in the dependent claims 2 to 4. The wording of all claims is hereby incorporated by reference into the content of this specification.

The method according to the invention is a method for producing electrode windings which has at least the following steps:

In step A, at least one strip or band-shaped anode is provided.

In a step B, flat negative arrester lugs are formed at varying distances on at least one longitudinal side of the at least one anode. Alternatively or additionally, in this step, a contour can also be cut into at least one longitudinal side of the at least one anode.

In a step C, at least one strip or ribbon-shaped cathode is provided.

In a step D, surface positive discharge lugs are formed at varying intervals on at least one longitudinal side of the at least one cathode. Alternatively or additionally, in this step, a contour can also be cut into at least one longitudinal side of the at least one anode. - -

In a step E, at least one strip or band-shaped separator is provided.

Optionally, in a step F, a contour is cut into at least one longitudinal side of the at least one separator.

In a step G, the at least one anode, the at least one cathode and the at least one separator are wound into a winding having the sequence anode / separator / cathode, in particular spirally wound.

The steps A to E and G are mandatory part of the method according to the invention, the step F is an optional step, which plays a role especially in the production of asymmetric electrode winding. But more on that later.

Usually, either the anode or the cathode or even both electrodes are covered on both sides by a separator in order to avoid short circuits during winding. Thus, in step E, two or more separators are preferably provided and then wound up in step G. The production of sequences of the type anode / separator / cathode / separator / anode or cathode / separator / anode / separator / cathode is readily possible.

In preferred embodiments, discharge tabs may be formed on both longitudinal sides of the strip or ribbon anode and / or the strip or ribbon cathode. In these cases, collector tabs of like polarity protrude on opposite sides of the resulting electrode coil.

As is known, a strip or a band is a flat article whose length exceeds its width by a multiple and which preferably has a substantially uniform width over substantially its entire length. Accordingly, the terms "strip or band-shaped" - - to understand in the present case. Thus, the length of usable in the context of the present invention anodes, cathodes and separators is usually between 0.25 m and 25 m, preferably between 0.5 m and 15 m. Their maximum width is preferably between 20 mm and 400 mm, preferably between 40 mm and 200 mm.

Since the Ableiterfahnen formed on the longitudinal sides of the electrodes and these are wound flat in the longitudinal direction, they usually protrude in the axial direction (relative to the winding axis), ie in particular the front side, out of the winding. The arrester lugs themselves are not in a wound form. Strictly speaking, they are therefore not part of the coil, but serve only for its electrical contact. It is thus possible to differentiate between a winding main body, which consists of the wound electrodes and separators, and the unwrapped discharge tabs protruding from the main body.

In accordance with the above-described problem, it is preferred that in step F wraps are obtained in which the protruding from the winding conductor tabs are arranged overlapping in a kind of stack-shaped arrangement. As mentioned above, the arrester lugs are flat, for example rectangular or square, formed, usually they have two opposite flat sides, the flat in the finished winding or, especially in spiral windings, also bent (the one flat side convex, the other concave) may be present. An overlapping arrangement is to be understood in particular as meaning that the flat sides of all the discharge lugs within the stacked arrangement overlap in one direction, preferably perpendicular to the flat sides, preferably at least 75%, more preferably at least 90%, in particular at least 95%. As a result, the arrester lugs have only a minimal offset within the stacked arrangement relative to each other. - -

Preferably, all the collector tabs are dimensioned the same size within a stack-shaped arrangement, but this is not absolutely necessary.

In particular, the method according to the invention is characterized in that the step G overlaps in time with at least one of the steps B or D, in particular with both steps, and optionally also with the step F. That is, according to the present method, an electrode strip or electrode tape is not first completed and then wound up in a downstream, separate step. Rather, according to the method of the invention, processing of the electrode strips and the at least one separator into a winding is started before all the collector lugs are formed along the at least one longitudinal side of the at least one anode and / or cathode and / or before the contour cut on the longitudinal sides of the Electrodes and the at least one separator is completed.

According to the method of the invention, it is preferred that at least one of the parameters is determined via one or more sensors

, relative positioning of the positive collector tabs relative to each other (in the resulting electrode coil),

, relative positioning of the negative collector tabs to one another (in the resulting electrode coil),

, relative positioning of the positive arrester lugs to the negative ones

Ableiterfahnen (in the resulting electrode winding), relative

Positioning the at least one cathode to at least one

Anode (in the resulting electrode winding),

, relative positioning of the at least one separator to the at least one cathode and / or to the at least one anode (in the resulting electrode winding), - -

, Thickness and / or geometry of the at least one anode, in particular thickness and / or geometric profile of the at least one strip-shaped or band-shaped anode in the longitudinal direction,

, Thickness and / or geometry of the at least one cathode, in particular thickness and / or geometric course of the at least one strip or ribbon-shaped cathode in the longitudinal direction, and

, Thickness and / or geometry of the at least one separator, in particular thickness and / or geometric profile of the at least one strip or belt-shaped separator in the longitudinal direction, is detected and depending on the measurement result

- The distances between the still to be formed in step B and / or step D Ableiterfahnen be nachkorrigiert and / or

- The contours to be cut for the longitudinal sides of the electrodes and / or the at least one separator are nachkorrigiert.

The aim of the measurements is to detect possible deviations from the calculated position of the collector lugs, the electrodes and / or the separators in the winding, in particular as a result of variations in the thickness of the electrodes and / or separators, and the resulting staggered arrangement of the collector lugs , Counteract electrodes and / or separators in the resulting winding by the position of the still to be formed Ableiterfahnen and / or the contours to be cut on the not yet wound part of the anode, cathode or Separatorstreifens is corrected accordingly. The method according to the invention is appropriate - - preferred by a regulated method and not by a controlled only.

The formation of the collector tabs preferably takes place via a cutting process, in particular with the aid of at least one laser. Both the contours of electrodes and separators and the Ableiterfahnen are therefore preferably cut out. Particularly preferably, during the contour cutting of the electrodes, the collector tabs are also cut out at the same time.

As mentioned above, for the production of electrodes of batteries and battery cells in a coating process usually pastes comprising electrochemically active and inactive components are applied to electrical arresters, dried and brought into the desired fit. The latter step optionally also includes the cutting out of the collector tabs. The arresters are usually provided in the form of endless belts, which have uncoated edge regions on the longitudinal sides with central coating, from which the arrester vanes can be cut out. In preferred embodiments, the edge contours of anode and cathode are determined at the same time.

As a rule, tape-shaped films, grids and networks made of metal are used as arresters for battery electrodes. In the case of lithium-ion batteries, arresters of copper (on the anode side) and aluminum (on the cathode side) are particularly preferred.

Both the coated and uncoated areas of the arresters can be easily laser cut. The use of lasers for cutting electrodes is already known, for example, from EP 465 628 B1. In a method according to the invention, more than one laser, preferably two to eight lasers, are preferably used, with which at the same time the - -

Ableiterfahnen and the contours of the anode and cathode can be cut.

According to the preferred embodiments described above, the tabs of electrodes for batteries are formed, in particular by a cutting operation, of an arrester which is at least partially covered with a paste comprising electrochemically active and inactive components. Arrester and Ableiterfahnen the electrodes can thus be integrally formed.

By appropriately trimming the longitudinal edges of the electrodes can be obtained basically in any geometry wraps. The classic spiral winding has a cylindrical base body and thus a very high symmetry. Depending on the application, it may be desirable to produce flat, non-rotationally symmetric winding with an oval winding course or even winding which has a winding base body with a cross-section which changes in the axial direction (asymmetrical windings). Especially in the case of the latter, not only the positioning of the collector tabs is important, but also the electrodes and separators must not be offset with respect to one another in the coil. Accordingly, it is important to monitor by means of the mentioned sensors, the relative positioning of the at least one cathode to at least one anode to each other and the electrodes to the at least one separator in the resulting electrode coil and adjust if necessary, the contours still to be cut.

The strip-shaped or band-shaped anode and the strip-shaped or ribbon-shaped cathode can be both the electrodes of a battery cell and the electrodes of a capacitor. Accordingly, the inventive method both for the production of battery cells and for the production of - -

Serve capacitors. With regard to the selection of materials for the electrodes and also for suitable separators, reference is made in both cases to the statements in the introductory part of the present description.

A device for the production of electrode coils, in particular according to a method according to the invention, is the subject of the present invention. Such a device comprises

Means for providing at least one strip or band-shaped anode,

Means for providing at least one strip or ribbon-shaped cathode,

Means for providing at least one strip or belt-shaped separator and

Means for winding the at least one anode, the at least one cathode and the at least one separator to form a winding with the sequence anode / separator / cathode, wherein the means are usually a conventional winding device for producing electrode windings and suitable Transport devices for feeding the winding device with band-shaped electrodes and separators is. Furthermore, the device according to the invention comprises

Means for forming flat negative discharge lugs at varying distances on at least one longitudinal side of the at least one anode and / or means for cutting a contour in at least one longitudinal side of the at least one anode

Means for forming surface positive tabs at varying intervals on at least one longitudinal side of the at least one cathode and / or means for cutting a - -

Contour in at least one longitudinal side of the at least one cathode, as well

- Where appropriate, means for cutting a contour in at least one longitudinal side of the at least one separator.

In accordance with the above statements regarding the method according to the invention, these are preferably cutting means, in particular at least one laser.

In particular, a device according to the invention is characterized in that it comprises at least one sensor for determining at least one of the possible deviations from the calculated position of the discharge lugs, the electrodes and / or the separators in the winding, in particular as a consequence of variations in the thickness the electrodes, relevant parameters (see above) and a data processing and control device which detects the measurement results of the at least one sensor and depending on the same the means for forming the flat Ableitfahnen corrections regarding the distances or the variation of the distances between the still trainees Ableiterfahnen and / or the means for cutting the contour into the at least one longitudinal side of the at least one cathode, the at least one anode and / or the at least one separator provides a corrected contour specification.

With the method according to the invention and the device according to the invention, it is possible to produce winding electrodes for galvanic cells or capacitors in practically any desired formats. Particularly preferably four to eight lasers are used as cutting means with which the at least one anode, the at least one cathode and the at least one separator can be cut simultaneously. By means of at least one mechanical or electronic measuring sensor on the winding device, the relative positions - - Of electrodes and separators in the resulting winding constantly checked and automatically be corrected by a complex computer program. As a result, for example, the above-described influences of thickness variations of the electrodes on the positioning of the collector tabs can be almost completely eliminated.

In practice, a cutting pattern progressively changing in length for each electrode and each separator is usually specified with a position of the collector lugs calculated taking into account the winding circumference and the average material thicknesses. The individual layers (electrode and separators) are virtually positioned in the computer to each other, then cut and wound according to the predetermined pattern. In this case, the positioning of the layers to each other by means of sensors is continuously detected and, if necessary, automatically corrected via a lying above the pattern computer plane simultaneously for all layers.

Particularly preferably, the lasers are operated in parallel and driven by a complex machine program so that winding and Ableiterfahnen can be created in almost any geometry. A change of the cutting contour can e.g. about the loading of a graphic file e.g. in DXF format or by drawing the pattern directly on the user interface of a system computer.

The device according to the invention and the method according to the invention will be explained in more detail with reference to the drawings. It should be emphasized at this point that all facultative aspects of the device or the method according to the invention described in the present application in each case alone or in combination with one or more of the further optional aspects described in one embodiment of the invention - - can be realized. The following description of preferred embodiments is merely for the purpose of illustrating and understanding the invention and is in no way limiting.

A winding apparatus 101 is fed via the deflection rollers 102a to 102d with two belt-shaped separators 103 and 104 and a belt-shaped anode 105 and a belt-shaped cathode 106. In this device 101, the production of an electrode coil with the sequence separator / cathode / separator / anode takes place. With the aid of the lasers 107 and 108, the longitudinal sides of the band-shaped electrodes 105 and 106 are trimmed. In this case, the abovementioned arrester lugs are formed. Their positioning is adjusted via sensors at point 109. If necessary, the patterns for the still to be formed Ableiterfahnen, in particular their distances on the long sides, nachkorrigiert.

A device according to the invention with a total of eight lasers 201a to 201d as means for cutting electrodes and separators is shown in FIG. In this device, the production of an electrode coil with the sequence separator 1 / cathode / separator 2 / anode. The two separators 202 and 203 and the two electrodes 204 and 205 are each provided in a band-shaped form. The longitudinal sides of the separators 202 and 203 and the electrodes 204 and 205 are trimmed by the lasers. In this case, discharge lugs 207 are formed from uncoated edge regions 206 of the electrodes. At the same time, contours are cut into the longitudinal sides of the electrodes 204 and 205 and the separators 202 and 203, as seen in FIG. Electrodes having such contours can be used to obtain electrode windings which have a winding base body with an axially changing shape - -

Have cross-section (asymmetric electrode winding). The sensors 208a-d are used to perform a pattern inspection in which both the edge contours of the electrodes 204 and 205 and separators 202 and 203 and the relative positioning of the collector tabs are checked. If it is determined during the check that an offset occurs in the resulting winding, the cutting specifications for the lasers 201a to 201d are corrected during operation.

An electrode winding 300 of spirally wound electrodes and separators, as can be obtained, for example, with the method illustrated in FIG. 1, is shown on the left in FIG. 3. On the left is an overall view of the coil 300 with the cylindrical winding base 301, which is formed from a spirally wound composite of electrodes and separators. Furthermore, two groups of Ableiterfahnen 302 and 303 can be seen, which protrude from the end face of the winding 300. On the right is a plan view of the winding 300 shown on the left or on the front side of the coil 300 with the groups of Ableiterfahnen 302 and 303 shown and a partial enlargement of the same. It can be clearly seen that the individual collector lugs are arranged overlapping in the direction of the center of the coil 300. They form a kind of stack within which individual tabs completely overlap with adjacent ones. The partial enlargement shows that the individual collector lugs have only a minimal radial offset from one another. Such precise results can be obtained without problems by means of the method according to the invention.

FIG. 4 shows the electrode winding 400 with the winding base body 401 and with the positive headers 402 and the negative headers 403. As already mentioned, the winding base body 401 has an axially changing cross-section. Such a winding can be produced from the band-shaped separators A and C and the band-shaped electrodes B and D. Depicted are fragments of - -

Bands after the contour cut, for example by laser of a device according to FIG. 2. Emphasized are the distances X, Y and Z, which increase in the separators and electrodes A to D from left to right. This increase is necessary to compensate for the increasing winding radius when the illustrated belt-shaped electrodes and separators are wound starting from the left. In E, a not yet wound composite of the electrodes and separators A to D is shown.

FIG. 5 shows further embodiments of asymmetric electrode coils which can be produced according to the method according to the invention. The coils shown in FIGS. 5A and 5B have groups of negative and positive dischargers on two opposite end faces. In contrast, FIG. 5C shows a winding in which the positive and negative discharge lugs protrude from the electrode winding on the same end face.

Claims

claims

A method of making electrode coils comprising the steps

(A) providing at least one strip-shaped or band-shaped anode,

(B) forming flat negative collector tabs at varying distances on at least one longitudinal side of the at least one anode and / or cutting a contour in at least one longitudinal side of the at least one anode,

(C) providing at least one strip or ribbon-shaped cathode,

(D) forming surface positive tabs at varying intervals on at least one longitudinal side of the at least one cathode and / or cutting a contour in at least one longitudinal side of the at least one cathode

(E) providing at least one strip or ribbon-shaped separator,

(F) optionally cutting a contour in at least one longitudinal side of the at least one separator and

(G) winding the at least one anode, the at least one cathode and the at least one separator into a winding with the sequence anode / separator / cathode, characterized in that the step (G) at least one of steps (B) or (D ) and optionally (F) overlapped in time.

A method according to claim 1, characterized in that at least one of the parameters via at least one sensor relative positioning of the positive discharge lugs relative to one another,

relative positioning of the negative arrester tabs to one another,

relative positioning of the positive discharge lugs to the negative discharge lugs,

relative positioning of the at least one cathode to the at least one anode,

relative positioning of the at least one separator to the at least one cathode and / or to the at least one anode,

Thickness and / or geometry of the at least one anode, in particular thickness and / or geometric profile of the at least one strip-shaped or band-shaped anode in the longitudinal direction,

Thickness and / or geometry of the at least one cathode, in particular thickness and / or geometric course of the at least one strip or ribbon-shaped cathode in the longitudinal direction, and

Thickness and / or geometry of the at least one separator, in particular thickness and / or geometric profile of the at least one strip or belt-shaped separator in the longitudinal direction, is detected and depending on the measurement result

- The distances between the in step (B) and / or (D) still trainees Ableiterfahnen be corrected and / or - The contours to be cut for the longitudinal sides of the electrodes and / or the at least one separator are nachkorrigiert.

3. The method of claim 1 or claim 2, characterized in that the formation of the Ableitfahnen a cutting process, in particular by means of at least one laser comprises.

4. The method according to any one of claims 1 to 3, characterized in that it is the electrodes of a battery cell or a capacitor in the strip or band-shaped anode and the strip or band-shaped cathode.

5. Apparatus for carrying out a method according to one of the preceding claims, comprising

Means for providing at least one strip or band-shaped anode,

Means for providing at least one strip or ribbon-shaped cathode,

Means for forming flat positive discharge lugs at varying distances on at least one longitudinal side of the at least one cathode and / or means for cutting a contour in at least one longitudinal side of the at least one cathode,

Means for providing at least one strip or belt-shaped separator, Optionally, means for cutting a contour in at least one longitudinal side of the at least one separator, and

Means for winding the at least one anode, the at least one cathode and the at least one separator into a winding having the sequence anode / separator / cathode,

at least one sensor for determining at least one of the relative positioning of the positive collector tabs relative to each other, relative positioning of the negative tabs relative to each other, relative positioning of the positive tabs to the negative arrester tabs, relative positioning of the at least one cathode to at least one anode, relative positioning of the at least one separator at least one cathode and / or at least one anode, thickness and / or geometry of the at least one anode, in particular thickness and / or geometric course of the at least one anode in the longitudinal direction, thickness and / or geometry of the at least one cathode, in particular thickness. and / or geometric course of the at least one cathode in the longitudinal direction, and thickness and / or geometry of the at least one separator, in particular thickness and / or geometric course of the at least one separator in the longitudinal direction, and

- A data processing and control device which detects the measurement results of the at least one sensor and depending on the means for forming the planar Ableitfahnen distances or the variation of the distances between the Ableitfahnen on at least one longitudinal side of the at least one cathode and / or the at least one Anode pretends and / or the means for cutting the contour in the at least one longitudinal side of the at least one cathode, the at least one anode and / or the at least one separator supplies a corrected contour specification.